Post on 24-Sep-2020
Industrial Trend of Semiconductor I (in Aspect of Display)
Grad. School of Management of TechnologyHoseo University
Hee-Woon Cheong
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Process of Social Development
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▪ ~2020 : Combination of industrial society and information society▪ 2020~ : Advent in “Conscious Technology”
What is Display?
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Definition A device that visualizes data as characters or figures
Role A terminal that provides information to human being
Purpose Transfer information from sources to human being through visual senses
interface interface
Display Tree
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Display
CRT FPD
Emissive Transmissive
PDP OLED LCD
CPT
CDT
Display History
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From lecture notes in “Display Engineering” by K. W. Whang, 2013
History of CRT Development
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B/W CRT (1897) CPT (1950) CDT (1980)
Karl Ferdinand Braun Edward W. Herold(RCA)
Eiichi Yamazaki(Hitachi)
History of PDP Development
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Mono-PDP (1927) AC PDP (1964) DC PDP (1969)
Frank Gray(Bell Lab.)
H. Gene Slottow& Donald L. Bitzer (Illinois)
W. S. Burroughs(Burroughs Co.)
50×50 lines,Ne discharge
History of LCD Development
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TN mode LCs (1962) TN mode LCDs (1968) IPS mode LCDs (1992)
Martin Schadt(Roche)
George H. Heilmeier(RCA)
G. Baur(Fraunhofer Institute)
Early History of FPD Industry in Korea
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From lecture notes in “Display Engineering” by S. T. Shin, 2014
History of OLED Development
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1st OLED (1987) 1st AMOLED (2002) AMOLED TV (2013)
Ching W. Tang(Kodak)
LG Display @ CES 2013Kodak Easyshare
History of 3-D Display Development
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1st 3-D display (1838) 1st holographic 3-D (1964) Full HD 3D TV (2010~)
Sir Charles Wheatstone
LG Display 55” (2011)
Leith and Upatnieks
Samsung Display 65” (2010)
3-D Market Forecast
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Shipments Revenues
Displaysearch, 2010Displaysearch, 2012
3-D Market Forecast (cont’d)
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3D Market by Devices 3D Market / Total Market
Displaysearch, 2010Displaysearch, 2010
History of Flexible Display Development
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Flexible e-paper (2008) E-reader (2010) Flexible screen (2012)
by E Ink Holdings Samsung DisplayPlastic Logic @ CES 2010
R&D Trend in Flexible LCD
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From lecture notes in “Display Engineering” by S. T. Shin, 2014
R&D Trend in Flexible OLED
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From lecture notes in “Display Engineering” by S. T. Shin, 2014
Trends and Variations
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Performance Comparisons
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CRTFPD
PDP LCD OLED
Pros
Cons
Size
Status
Application
Issue
Monitor / TV TVMonitor / TVLaptopMobile / Tablet
Monitor / TVLaptopMobile / Tablet
10” ~ 40” 32” ~ 150” 2” ~ 108” 2” ~ 77”
Image quality ↑Price ↓
Weight, thickness ↓Price ↓Power ↓Resolution ↑Enlargement ↑
Thickness ↓Price ↓Image quality ↑Response time ↓Enlargement ↑
Weight, thickness ↓Power ↓Resolution ↑Response time ↓
Weight, Vol. ↑Size ↓
Viewing angle ↓Response time ↑
Power ↑Temp. ↑
Price ↑Lifetime ↓Enlargement ↓
N/A High efficiency High resolution
Fast response timeFlexibility
Long lifetimeEnlargementMass production
Withdrawal Mass-producing(mature)
Mass-producing(mature)
Mass-producing(initial)
Performance Comparisons (cont’d)
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From lecture notes in “Display Engineering” by K. W. Whang, 2013
CRT평판 Display
TFT-LCD PDP 유기EL
두께 △ ◎ ◎ ◎
대형화 ○ ○ ◎ ×
중량 × ◎ ◎ ◎
색도 ◎ ○ ◎ ◎
휘도 ◎ ○ ◎ ◎
시야각 ◎ ○ ◎ ◎
응답속도 ◎ △ ◎ ◎
고정세 ◎ ◎ ○ ◎
소비전력 ○ ◎ △ ◎
신뢰성 ◎ ◎ ○ △
◎Excellent, ○Good, △Average, ×Poor
World’s Largest 152-inch 3D PDP
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Characteristics of PDP
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Non-linearity
Memory effect
Current flows when > by -process
Sustainable discharge by wall charges
X electrode
Y electrode
X electrode
Y electrode
Advantages
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Wide viewing angle
Long lifetime
Displaybank, 2004
Displaybank, 2004
Good dynamic image quality (motion blur)
Disadvantages
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Low luminous efficiency
Heavy weight
Structure
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Light Emission from PDP
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LG Display vlog, 2014.4
-process in plasma discharge
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▪ = (− )▪ = (− ) for inert gas
-process in plasma discharge
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Various reactions at surface Auger neutralization
-value of Alkaline Earth Metal Oxides
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Energy (eV) -values
Motoyama, Ph. D. dissertation
: electrons from cathode : electrons arriving cathode : electrode gap
= − ( − ) = − ( − )
Breakdown Condition
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For breakdown, − =
Driving Waveform
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Reset Address Sustain
Address
Sustain
• Ramp-up : Accumulation of wall charges (Y : anode)• Ramp-down : Elimination of wall chargesReset
• Selection of cells for picture display
• Picture display of selected cells
Reset, Address and Sustain in PDP
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W. J. Lee, DisplayZine, 2009
Gray Scale Using ADS (Address-Display Separation)
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▪ 256 (= ) gray scale can be realized in PDP
Gray Scale Using ADS : Case Study
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Intensity ofSF3 (= )
Intensity ofSF2 (= )
Intensity ofSF1 (= )Data Total
000
001
010
011
100
101
110
111
0
0
0
0
4
4
4
4
0
0
2
2
0
0
2
2
0
1
0
1
0
1
0
1
0
1
2
3
4
5
6
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▪ 8 (= ) gray scale can be realized with 3bit data
Gray Scale Using AWD (Address While Display)
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▪ Timely and efficient manner
History of Commercial PDP Development
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▪Mono AC PDP (60”) commercialized by Photonics (1988)▪ DC PDP (20”) commercialized by NHK (1988)
▪ DC PDP commercialized by Matsushita (early 1980s)▪ Start R&D for DC PDP (HD) in NHK (early 1980s)
1980s
▪ Start R&D in NHK, Hitachi, Fujitsu, Sony etc.
1970s
▪AC PDP (21”) commercialized by Fujitsu (1993)▪ Full color DC PDP (40” HD) commercialized by Fujitsu (1993)▪ PDP (30” XGA) commercialized by Plasma Co. (1993)
▪ 64-gray scale AC PDP commercialized by Photonics (1991)▪ 0.4mm-pitch AC PDP (22”) commercialized by Thomson Tube (1992)
1990s
▪ Start mass production of PDP in Samsung SDI, LG Electronics (2000)▪ Full color PDP (80” FHD) commercialized by Samsung SDI(2004)
2000s
History of Commercial PDP Development (cont’d)
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▪ Full Color AC PDP (103” FHD) commercialized by Samsung SDI (2005)▪AC PDP (65” FHD) commercialized by Matsushita (2005)▪AC PDP (32” XGA) commercialized by Samsung SDI, LG Electronics (2007)▪AC PDP (150”) displayed by Panasonic (2008)▪ Hitachi, Pioneer withdraw from PDP industry (2008)
2005~
▪AC PDP (3-D, 152”) displayed by Panasonic (2010)▪ Panasonic withdraw from PDP industry (2013)▪ Samsung SDI, LG Electronics are planning to withdraw from PDP industry (2014~)
2010~
World’s Largest 108-inch 3D LCD
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Light Emission from LCD
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LG Display vlog, 2014.4
Structure
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BLU (Back Light Unit)
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Direct-Lit Edge-Lit
Structure of Direct-Lit BLU
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Diffuser Plate in Direct-Lit BLU
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Roles
Lamp screening
Supporter of diffusion films
Excellent Poor
From lecture notes in “Display Engineering” by S. T. Shin, 2014
Diffusion Film in Direct-Lit BLU
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http://www.soken-ce.co.jp/
Binder resin
Base film
Antiblocking layer
Diffusion agent / Diffusion ↑ and Luminance ↑ by “Beads”
PET film / Straightness
Preventing electrification, adhesion to diffuser plate
Structure of Edge-Lit BLU
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Light Guide Panel (LGP) in Edge-Lit BLU
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▪ Transmit light to the diffusion film uniformly by light scattering
Light Scattering by Patterns in LGP
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Without patterns With pattern
Polarizing Filters
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Operation Principle
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Light does not transmits.Light transmits.
LC (Liquid Crystal)
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Characteristics of LC
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3-DLattice 1-D or 2-D N/A
OOrientation O X
SolidStatus Fluid Fluid
Various LC Modes
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Kristopher Kubicki, ANANDTECH, 2003
TN (Twisted Nematic) Mode
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▪ OFF : White▪ ON : Black
Pros and Cons of TN Mode
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Pros
Cons
▪ Low driving voltage, low cost▪ Fast response time (VA > IPS > TN)
▪ Narrow viewing angle (IPS > VA > TN)
IPS (In Plane Switching) Mode
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▪ LC rotates parallel to the glass substrate due to the external magnetic field.▪ Commercialized by LG Display, Sharp etc.
http://photohistory.tistory.com/12815
Pros and Cons of IPS Mode
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Pros
Cons
▪Wide viewing angle ← Parallel alignment▪ Fast response time (VA > IPS > TN) ← Low resistance Cu wiring▪ High color gamut (VA, IPS > TN) ← No optical films
▪ Low contrast ratio (VA > IPS > TN) ← Backlight bleeding
S-IPS (Super IPS) Mode
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▪ Improved response time
AH-IPS (Advanced High performance IPS) Mode
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▪ Brightness ↑ and power consumption ↓▪ “Ratina display” in Apple’s iPhone
VA (Vertical Alignment) Mode
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▪ OFF : LC is aligned vertically with respect to the glass substrate.▪ ON : LC is aligned in parallel with the glass substrate.▪ Commercialized by Samsung Display etc.
Pros and Cons of VA Mode
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Pros
Cons
▪Wide viewing angle (IPS > VA > TN)▪ High contrast ratio (VA > IPS > TN) ← LC alignment▪ High color gamut (VA, IPS > TN) ← High contrast ratio
▪ Slow response time (VA > IPS > TN)▪ Pressure-sensitive and poor restoring force → Trouble in smartphone use
MVA (Multi-domain VA) Mode
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A. Takeda, et al., SID 98
Operation Viewing angle : VA vs MVA
▪ Good viewing angle due to the symmetric LC domain.
PVA (Patterned-electrode VA), S-PVA Mode
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▪A substrate with patterned ITO slit increases the contrast ratio.▪ 8-Domain cell provides wide viewing angle, fast response time.
Performance Comparisons
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TN IPS VA
Viewing angle Poor Excellent Good
Response time Excellent Good Normal
Contrast ratio Normal Good Excellent
Color gamut Normal Excellent Excellent
Cost Excellent Normal Normal
Manufacturer Many others LG Display, Sharp Samsung Display
Development continues by Global Corporations
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